Improving seismotectonics and seismic hazard assessment along the San Ramo´n Fault at the eastern border of Santiago city, Chile
Author
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Pérez Rojas, Alejandro
es_CL
Author
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Ruiz, J. A.
es_CL
Author
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Vargas Easton, Víctor
es_CL
Author
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Rauld, R.
es_CL
Author
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Rebolledo, S
Author
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Campos Muñoz, Jaime
Admission date
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2015-01-06T18:17:49Z
Available date
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2015-01-06T18:17:49Z
Publication date
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2014
Cita de ítem
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Nat Hazards (2014) 71:243–274
en_US
Identifier
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DOI: 10.1007/s11069-013-0908-3
Identifier
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https://repositorio.uchile.cl/handle/2250/126928
General note
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Artículo de publicación ISI
en_US
Abstract
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The San Ramo´n Fault is an active west-vergent thrust fault system located
along the eastern border of the city of Santiago, at the foot of the main Andes Cordillera.
This is a kilometric crustal-scale structure recently recognized that represents a potential
source for geological hazards. In this work, we provide new seismological evidences and
strong ground-motion modeling from hypothetic kinematic rupture scenarios, to improve
seismic hazard assessment in the Metropolitan area of Central Chile. Firstly, we focused on
the study of crustal seismicity that we relate to brittle deformation associated with different
seismogenic fringes in the main Andes in front of Santiago. We used a classical hypocentral
location technique with an improved 1D crustal velocity model, to relocate crustal
seismicity recorded between 2000 and 2011 by the National Seismological Service, University
of Chile. This analysis includes waveform modeling of seismic events from local
broadband stations deployed in the main Andean range, such as San Jose´ de Maipo, El
Yeso, Las Melosas and Farellones. We selected events located near the stations, whose
hypocenters were localized under the recording sites, with angles of incidence at the
receiver\5 and S–P travel times\2 s. Our results evidence that seismic activity clustered
around 10 km depth under San Jose´ de Maipo and Farellones stations. Because of their
identical waveforms, such events are interpreted like repeating earthquakes or multiplets
and therefore providing first evidence for seismic tectonic activity consistent with the crustal-scale structural model proposed for the San Ramo´n Fault system in the area (Armijo
et al. in Tectonics 29(2):TC2007, 2010). We also analyzed the ground-motion variability
generated by an Mw 6.9 earthquake rupture scenario by using a kinematic fractal k-2
composite source model. The main goal was to model broadband strong ground motion in
the near-fault region and to analyze the variability of ground-motion parameters computed
at various receivers. Several kinematic rupture scenarios were computed by changing
physical source parameters. The study focused on statistical analysis of horizontal peak
ground acceleration (PGAH) and ground velocity (PGVH). We compared the numerically
predicted ground-motion parameters with empirical ground-motion predictive relationships
from Kanno et al. (Bull Seismol Soc Am 96:879–897, 2006). In general, the synthetic
PGAH and PGVH are in good agreement with the ones empirically predicted at various
source distances. However, the mean PGAH at intermediate and large distances attenuates
faster than the empirical mean curve. The largest mean values for both, PGAH and PGVH,
were observed near the SW corner within the area of the fault plane projected to the
surface, which coincides rather well with published hanging-wall effects suggesting that
ground motions are amplified there.
en_US
Patrocinador
dc.description.sponsorship
Millennium Nucleus on Seismotectonics and Seismic Hazard, International Earthquake
Research Center, Montessus de Ballore (CIIT-MB), Grant P06-064-F, and CEGA (Andean Geothermal
Center of Excelence) Fondap Project 15090013.